| blob | 729d4b15b645aa49c6eca2f003ebbd66f371796c |
1 /*
2 * Copyright (C) 2008, 2009 Intel Corporation
3 * Authors: Andi Kleen, Fengguang Wu
4 *
5 * This software may be redistributed and/or modified under the terms of
6 * the GNU General Public License ("GPL") version 2 only as published by the
7 * Free Software Foundation.
8 *
9 * High level machine check handler. Handles pages reported by the
10 * hardware as being corrupted usually due to a 2bit ECC memory or cache
11 * failure.
12 *
13 * Handles page cache pages in various states. The tricky part
14 * here is that we can access any page asynchronous to other VM
15 * users, because memory failures could happen anytime and anywhere,
16 * possibly violating some of their assumptions. This is why this code
17 * has to be extremely careful. Generally it tries to use normal locking
18 * rules, as in get the standard locks, even if that means the
19 * error handling takes potentially a long time.
20 *
21 * The operation to map back from RMAP chains to processes has to walk
22 * the complete process list and has non linear complexity with the number
23 * mappings. In short it can be quite slow. But since memory corruptions
24 * are rare we hope to get away with this.
25 */
27 /*
28 * Notebook:
29 * - hugetlb needs more code
30 * - kcore/oldmem/vmcore/mem/kmem check for hwpoison pages
31 * - pass bad pages to kdump next kernel
32 */
34 #include <linux/kernel.h>
35 #include <linux/mm.h>
36 #include <linux/page-flags.h>
37 #include <linux/sched.h>
38 #include <linux/rmap.h>
39 #include <linux/pagemap.h>
40 #include <linux/swap.h>
41 #include <linux/backing-dev.h>
50 /*
51 * Send all the processes who have the page mapped an ``action optional''
52 * signal.
53 */
56 {
67 #ifdef __ARCH_SI_TRAPNO
69 #endif
71 /*
72 * Don't use force here, it's convenient if the signal
73 * can be temporarily blocked.
74 * This could cause a loop when the user sets SIGBUS
75 * to SIG_IGN, but hopefully noone will do that?
76 */
82 }
84 /*
85 * Kill all processes that have a poisoned page mapped and then isolate
86 * the page.
87 *
88 * General strategy:
89 * Find all processes having the page mapped and kill them.
90 * But we keep a page reference around so that the page is not
91 * actually freed yet.
92 * Then stash the page away
93 *
94 * There's no convenient way to get back to mapped processes
95 * from the VMAs. So do a brute-force search over all
96 * running processes.
97 *
98 * Remember that machine checks are not common (or rather
99 * if they are common you have other problems), so this shouldn't
100 * be a performance issue.
101 *
102 * Also there are some races possible while we get from the
103 * error detection to actually handle it.
104 */
111 };
113 /*
114 * Failure handling: if we can't find or can't kill a process there's
115 * not much we can do. We just print a message and ignore otherwise.
116 */
118 /*
119 * Schedule a process for later kill.
120 * Uses GFP_ATOMIC allocations to avoid potential recursions in the VM.
121 * TBD would GFP_NOIO be enough?
122 */
127 {
139 }
140 }
144 /*
145 * In theory we don't have to kill when the page was
146 * munmaped. But it could be also a mremap. Since that's
147 * likely very rare kill anyways just out of paranoia, but use
148 * a SIGKILL because the error is not contained anymore.
149 */
154 }
158 }
160 /*
161 * Kill the processes that have been collected earlier.
162 *
163 * Only do anything when DOIT is set, otherwise just free the list
164 * (this is used for clean pages which do not need killing)
165 * Also when FAIL is set do a force kill because something went
166 * wrong earlier.
167 */
170 {
175 /*
176 * In case something went wrong with munmaping
177 * make sure the process doesn't catch the
178 * signal and then access the memory. Just kill it.
179 * the signal handlers
180 */
186 }
188 /*
189 * In theory the process could have mapped
190 * something else on the address in-between. We could
191 * check for that, but we need to tell the
192 * process anyways.
193 */
199 }
202 }
203 }
206 {
212 }
214 /*
215 * Collect processes when the error hit an anonymous page.
216 */
219 {
236 }
237 }
239 out:
241 }
243 /*
244 * Collect processes when the error hit a file mapped page.
245 */
248 {
254 /*
255 * A note on the locking order between the two locks.
256 * We don't rely on this particular order.
257 * If you have some other code that needs a different order
258 * feel free to switch them around. Or add a reverse link
259 * from mm_struct to task_struct, then this could be all
260 * done without taking tasklist_lock and looping over all tasks.
261 */
272 pgoff) {
273 /*
274 * Send early kill signal to tasks where a vma covers
275 * the page but the corrupted page is not necessarily
276 * mapped it in its pte.
277 * Assume applications who requested early kill want
278 * to be informed of all such data corruptions.
279 */
282 }
283 }
286 }
288 /*
289 * Collect the processes who have the corrupted page mapped to kill.
290 * This is done in two steps for locking reasons.
291 * First preallocate one tokill structure outside the spin locks,
292 * so that we can kill at least one process reasonably reliable.
293 */
295 {
306 else
309 }
311 /*
312 * Error handlers for various types of pages.
313 */
320 };
327 };
329 /*
330 * Error hit kernel page.
331 * Do nothing, try to be lucky and not touch this instead. For a few cases we
332 * could be more sophisticated.
333 */
335 {
337 }
339 /*
340 * Already poisoned page.
341 */
343 {
345 }
347 /*
348 * Page in unknown state. Do nothing.
349 */
351 {
354 }
356 /*
357 * Free memory
358 */
360 {
362 }
364 /*
365 * Clean (or cleaned) page cache page.
366 */
368 {
376 /*
377 * For anonymous pages we're done the only reference left
378 * should be the one m_f() holds.
379 */
383 /*
384 * Now truncate the page in the page cache. This is really
385 * more like a "temporary hole punch"
386 * Don't do this for block devices when someone else
387 * has a reference, because it could be file system metadata
388 * and that's not safe to truncate.
389 */
392 /*
393 * Page has been teared down in the meanwhile
394 */
396 }
398 /*
399 * Truncation is a bit tricky. Enable it per file system for now.
400 *
401 * Open: to take i_mutex or not for this? Right now we don't.
402 */
413 }
415 /*
416 * If the file system doesn't support it just invalidate
417 * This fails on dirty or anything with private pages
418 */
421 else
423 pfn);
424 }
426 }
428 /*
429 * Dirty cache page page
430 * Issues: when the error hit a hole page the error is not properly
431 * propagated.
432 */
434 {
438 /* TBD: print more information about the file. */
440 /*
441 * IO error will be reported by write(), fsync(), etc.
442 * who check the mapping.
443 * This way the application knows that something went
444 * wrong with its dirty file data.
445 *
446 * There's one open issue:
447 *
448 * The EIO will be only reported on the next IO
449 * operation and then cleared through the IO map.
450 * Normally Linux has two mechanisms to pass IO error
451 * first through the AS_EIO flag in the address space
452 * and then through the PageError flag in the page.
453 * Since we drop pages on memory failure handling the
454 * only mechanism open to use is through AS_AIO.
455 *
456 * This has the disadvantage that it gets cleared on
457 * the first operation that returns an error, while
458 * the PageError bit is more sticky and only cleared
459 * when the page is reread or dropped. If an
460 * application assumes it will always get error on
461 * fsync, but does other operations on the fd before
462 * and the page is dropped inbetween then the error
463 * will not be properly reported.
464 *
465 * This can already happen even without hwpoisoned
466 * pages: first on metadata IO errors (which only
467 * report through AS_EIO) or when the page is dropped
468 * at the wrong time.
469 *
470 * So right now we assume that the application DTRT on
471 * the first EIO, but we're not worse than other parts
472 * of the kernel.
473 */
475 }
478 }
480 /*
481 * Clean and dirty swap cache.
482 *
483 * Dirty swap cache page is tricky to handle. The page could live both in page
484 * cache and swap cache(ie. page is freshly swapped in). So it could be
485 * referenced concurrently by 2 types of PTEs:
486 * normal PTEs and swap PTEs. We try to handle them consistently by calling
487 * try_to_unmap(TTU_IGNORE_HWPOISON) to convert the normal PTEs to swap PTEs,
488 * and then
489 * - clear dirty bit to prevent IO
490 * - remove from LRU
491 * - but keep in the swap cache, so that when we return to it on
492 * a later page fault, we know the application is accessing
493 * corrupted data and shall be killed (we installed simple
494 * interception code in do_swap_page to catch it).
495 *
496 * Clean swap cache pages can be directly isolated. A later page fault will
497 * bring in the known good data from disk.
498 */
500 {
504 /* Trigger EIO in shmem: */
510 }
513 }
516 {
522 }
525 }
527 /*
528 * Huge pages. Needs work.
529 * Issues:
530 * No rmap support so we cannot find the original mapper. In theory could walk
531 * all MMs and look for the mappings, but that would be non atomic and racy.
532 * Need rmap for hugepages for this. Alternatively we could employ a heuristic,
533 * like just walking the current process and hoping it has it mapped (that
534 * should be usually true for the common "shared database cache" case)
535 * Should handle free huge pages and dequeue them too, but this needs to
536 * handle huge page accounting correctly.
537 */
539 {
541 }
543 /*
544 * Various page states we can handle.
545 *
546 * A page state is defined by its current page->flags bits.
547 * The table matches them in order and calls the right handler.
548 *
549 * This is quite tricky because we can access page at any time
550 * in its live cycle, so all accesses have to be extremly careful.
551 *
552 * This is not complete. More states could be added.
553 * For any missing state don't attempt recovery.
554 */
556 #define dirty (1UL << PG_dirty)
557 #define sc (1UL << PG_swapcache)
558 #define unevict (1UL << PG_unevictable)
559 #define mlock (1UL << PG_mlocked)
560 #define writeback (1UL << PG_writeback)
561 #define lru (1UL << PG_lru)
562 #define swapbacked (1UL << PG_swapbacked)
563 #define head (1UL << PG_head)
564 #define tail (1UL << PG_tail)
565 #define compound (1UL << PG_compound)
566 #define slab (1UL << PG_slab)
567 #define buddy (1UL << PG_buddy)
568 #define reserved (1UL << PG_reserved)
579 /*
580 * Could in theory check if slab page is free or if we can drop
581 * currently unused objects without touching them. But just
582 * treat it as standard kernel for now.
583 */
586 #ifdef CONFIG_PAGEFLAGS_EXTENDED
589 #else
591 #endif
599 #ifdef CONFIG_HAVE_MLOCKED_PAGE_BIT
602 #endif
608 /*
609 * Catchall entry: must be at end.
610 */
612 };
614 #undef lru
617 {
623 pfn,
626 }
630 {
640 /* Could do more checks here if page looks ok */
641 /*
642 * Could adjust zone counters here to correct for the missing page.
643 */
646 }
648 #define N_UNMAP_TRIES 5
650 /*
651 * Do all that is necessary to remove user space mappings. Unmap
652 * the pages and send SIGBUS to the processes if the data was dirty.
653 */
656 {
670 /*
671 * This check implies we don't kill processes if their pages
672 * are in the swap cache early. Those are always late kills.
673 */
681 }
683 /*
684 * Propagate the dirty bit from PTEs to struct page first, because we
685 * need this to decide if we should kill or just drop the page.
686 */
696 pfn);
697 }
698 }
700 /*
701 * First collect all the processes that have the page
702 * mapped in dirty form. This has to be done before try_to_unmap,
703 * because ttu takes the rmap data structures down.
704 *
705 * Error handling: We ignore errors here because
706 * there's nothing that can be done.
707 */
711 /*
712 * try_to_unmap can fail temporarily due to races.
713 * Try a few times (RED-PEN better strategy?)
714 */
720 }
726 /*
727 * Now that the dirty bit has been propagated to the
728 * struct page and all unmaps done we can decide if
729 * killing is needed or not. Only kill when the page
730 * was dirty, otherwise the tokill list is merely
731 * freed. When there was a problem unmapping earlier
732 * use a more force-full uncatchable kill to prevent
733 * any accesses to the poisoned memory.
734 */
737 }
740 {
751 }
757 }
761 /*
762 * We need/can do nothing about count=0 pages.
763 * 1) it's a free page, and therefore in safe hand:
764 * prep_new_page() will be the gate keeper.
765 * 2) it's part of a non-compound high order page.
766 * Implies some kernel user: cannot stop them from
767 * R/W the page; let's pray that the page has been
768 * used and will be freed some time later.
769 * In fact it's dangerous to directly bump up page count from 0,
770 * that may make page_freeze_refs()/page_unfreeze_refs() mismatch.
771 */
775 }
777 /*
778 * Lock the page and wait for writeback to finish.
779 * It's very difficult to mess with pages currently under IO
780 * and in many cases impossible, so we just avoid it here.
781 */
785 /*
786 * Now take care of user space mappings.
787 */
790 /*
791 * Torn down by someone else?
792 */
797 }
804 }
805 }
806 out:
809 }
812 /**
813 * memory_failure - Handle memory failure of a page.
814 * @pfn: Page Number of the corrupted page
815 * @trapno: Trap number reported in the signal to user space.
816 *
817 * This function is called by the low level machine check code
818 * of an architecture when it detects hardware memory corruption
819 * of a page. It tries its best to recover, which includes
820 * dropping pages, killing processes etc.
821 *
822 * The function is primarily of use for corruptions that
823 * happen outside the current execution context (e.g. when
824 * detected by a background scrubber)
825 *
826 * Must run in process context (e.g. a work queue) with interrupts
827 * enabled and no spinlocks hold.
828 */
830 {
832 }